FR2485399A1 - SPRAY TUBE IN FULL CONE - Google Patents

Abstract

FULL CONE SPRAY TUBE, WHICH INCLUDES A CYLINDRICAL TURBULENCE CHAMBER, AN ARRIVAL OF LIQUID TANGENTIALLY OPENING INTO THIS LATTER AND AN OUTLET NOZZLE AXIALLY EXTENDING THE TURBULENCE CHAMBER AND AQUID OF THE TURBULENCE, AQUID INPUT TANGENTIALLY THROUGH THIS LATTER AND AN OUTLET NOZZLE AXIALLY EXTENDING THE TURBULENCE CHAMBER AND AQUID LIQUID, AQUID THAT FACTORY HOLLOWS AND BOSSES ON THE BOTTOM OF THE TURBULENCE CHAMBER WITH REGARD TO THE OUTLET NOZZLE, IN ORDER TO INFLUENCE THE FLOW OF THE LIQUID. BOTTOM 23 OF TURBULENCE CHAMBER 14 HAS SEVERAL HOLLOWS 25 OR SEPARATE BOSSES.

Description

The present invention relates to a solid cone spray nozzle,

  which comprises a cylindrical turbulence chamber, a liquid inlet opening tangentially into the latter and an outlet nozzle axially extending the turbulence chamber and flow direction perpendicular to the liquid inlet, and depressions and bosses machined on the bottom of the turbulence chamber facing the outlet nozzle, in order to influence the flow of the liquid. It is known to mount swirling plates in the

  nozzle bodies, in order to print a rotation of the liquid sprayed

  riser, before it passes through the outlet nozzle. The swirl plates of the solid cone spray nozzles usually have peripheral holes and a central hole. The flow of the liquid is thus divided into an axial component and a radial component in the nozzle body. A high feed pressure of the liquid substantially enhances the influence of the axial component of the flow. This results in a decrease in the angle of the jet. The swirl plate also greatly reduces or limits the internal volume of the nozzle body, which can lead to fouling in the latter. A swirl plate is finally an additional piece, to be machined with precision and

  leading to an increase in the number of production operations

  and assembly, as well as costs.

  The Federal Republic of Germany Patent Application No. 26 04 264 discloses a nozzle, in which a rotation of

  liquid inside the body is obtained without swirling plate-

  separated only by a tangential arrival of the liquid. It is an L-type nozzle, in which the direction of arrival of the

  liquid is perpendicular to the direction of exit of the liquid. The provisions

  However, the constructive designs of an L-shaped nozzle do not produce normal

  not a solid cone spray, but a hollow cone spray, which is unsuitable for certain applications requiring a superficial spray as regular as possible (for the cooling of rolled steel for example). Attempts have been made to produce a substantially conical liquid outlet jet by a crenate or toothed form of the outlet nozzle, but this. The solution is imperfect because it leads to a very irregular distribution of the liquid following the section of the cone. The patent application of the Federal Republic of Germany published under No. 26 04 264 proposes an improved solution, in which the turbulence chamber presents inside the body of the nozzle a bottom rising or raised

  downstream, and the outlet channel has a narrow side wall

  cie in the center and flared or flaring out gradually after the outlet, to facilitate the formation of a spray pattern

in full cone.

  A solid cone spray nozzle of the aforementioned type is

  further described in Soviet Patent No. 58 90 30. An opening

  The cruciform bore is machined in the bottom of the turbulence chamber of this known L-shaped nozzle to produce a solid cone spray. The invention aims to improve the action on the flow in a nozzle of the aforementioned type by a particular shape of the bottom of the

  turbulence chamber. According to an essential characteristic of

  vention, the bottom of the turbulence chamber presents several hollow

and / or separate bosses.

  The invention advantageously creates large free sections to

  the inside of the nozzle body, which avoids, partially-

  at least a risk of fouling. Free sections are determined solely by the size of the inlets and outlets. The arrangements according to the invention also make it possible to

  constant jet angle at various pressures, because the shape according to the in-

  does not divide the flow into an outer radial component

  and a central axial component in the nozzle.

  The bosses or recesses according to the invention are produced easily,

  by injection for example (when producing the bottom of the chamber

  plastic turbulence) or by uninterrupted milling, using coupled cutters (when producing the bottom of the metal turbulence chamber). They also have the following advantage over the prior art: when a fouling of the free spaces of the bottom of the turbulence chamber occurs in very rare cases, the continuation of the flow allows an automatic sweeping of the fouling. On the other hand, the passage section

  in the body of the nozzle is not reduced by possible fouling

  as long as the latter do not exceed the height of the

  wise on the bottom of the turbulence chamber. In other words, the spraying is never interrupted, even in the case of a certain fouling of the free spaces in the bottom of the turbulence chamber. This is essential to maintain operating conditions and to avoid significant disruptions in

  installations and processes where the nozzles according to the invention are

lisées.

  Any provision of the depressions and / or bosses separated on the bottom of the turbulence chamber is conceivable in principle. For

  in particular, and according to another characteristic

  However, the depressions and / or separate bosses preferably have a regular geometric layout. According to another characteristic of the invention, the recesses and / or bosses

  separated are equidistant and arranged in several rows

  pendiculaires. A particularly simple and economical production of the bottom of

  the turbulence chamber is obtained when, according to another characteristic,

  preferred embodiment of the invention, the depressions and / or separate bosses are made by machining the bottom of the turbulence chamber,

  perpendicular to its surface, using end mills.

  According to another advantageous characteristic of the invention, the hollows and / or bosses are polyhedral, and preferably cubic, pyramidal or truncated pyramid. A prismatic shape of the separate depressions or bosses is also conceivable. The aforementioned preferential geometric shapes of the bosses and recesses according to the invention are, however, adopted most often in order to allow the manufacture

  by machining as economical and simple as possible.

  When the bottom of the turbulence chamber is made in the form of an injection-molded plastic part, and according to another characteristic of the invention, the recesses and / or bosses are conical

  or frustoconical, the various cones may have a circular section

  cular, reniform, elliptical or oval. A rectangular shape to

  rounded corners is also conceivable for the production of

  wise and hollow by injection of plastic material.

  In order to allow a variation of the flow conditions as required or a replacement of the bottom of the possibly fouled turbulence chamber, and according to another advantageous feature of the invention, a demountable connection is provided between the bottom of the chamber. turbulence and the body of the nozzle forming said

  bedroom. According to another preferred feature of the invention

  tion, a piece of discord forming the bottom of the turbulence chamber is removably attached to the rear face of the body of the

nozzle, by means of a flange.

  According to another characteristic of the invention, the distance (A)

  between the hole or holes of arrival of the liquid, opening tangential-

  in the turbulence chamber and the point of the fracture piece forming the bottom of said chamber, the closest to the inlet bore, is equal to about one-tenth of the diameter of the orifice (s) of arrival of the liquid, measured according to the axis of the turbulence chamber. Uriah

  optimal influence on the liquid entering the turbulence chamber

  lence is thus guaranteed by the irregular shape of the bottom of said chamber according to the invention. The influence on the penetrating liquid is insufficient in the case of a greater distance and too strong in

the case of a lower distance.

  Other features and advantages of the invention will be

  better understood using the detailed description below of a

  exemplary embodiment and the accompanying drawings in which:

  FIG. 1 is the vertical longitudinal section of a spray nozzle.

  full cone (along axis I-I of Figure 2); Figure 2 is the section along the axis II-II of Figure 1; Figure 3 is the sectional view of another embodiment of the bottom of the turbulence chamber, along the axis II-III of Figure 4; and

  Figure 4 is the side elevation of the bottom according to Figure 3.

  The body 10 of the solid cone spray nozzle is

  1 and 2. It comprises a liquid inlet 11, formed laterally, with a narrowing inlet bore 12

  from the outside to the inside. A tapping 13 allows the connection

  of a pipe (not shown) of arrival of the liquid. A cylindrical turbulence chamber 14, in which the liquid inlet bore 12 opens tangentially, is formed in the body 10 of the nozzle. An outlet nozzle 15 is formed at the lower end of the nozzle shown in Figure 1; it shrinks comically outside and forms inside an exit 16 which

  shrinks first, then flares out. The penetrating liquid tan-

  approximately 11 in the body 10 of the nozzle is thus rotated, then deflected 900 before exiting through the orifice 16 under

  form of a full conical jet in the direction of the arrow 17.

  Figure 1 further shows that the rear end of the body 10 of the nozzle is closed by a piece of discord 18. The latter

  is stepped on both sides so as to form a fastening flange 19.

  The steps also form on each side of the discoidal part 18 cylindrical surfaces 20, 21, whose diameter is equal to the inside diameter of the turbulence chamber 14, and which thus center the discord piece 18 in the body 10 of the nozzle . The discord piece 18 has two end faces 22, 23 and can be fixed on the body of the nozzle in two positions offset by 180 relative to

  transverse axis, so that each of these faces can

  storing the rear closure (the bottom) of the turbulence chamber 14. In the exemplary embodiment shown, the front face 23 of the discording piece 18 constitutes the bottom of the turbulence chamber 14. This bottom 23 is fixed so removable on the body 10 of the

  nozzle forming said chamber 14. The bottom 23 of the turbulence chamber

  lence 14 is generally plane and perpendicular to the longitudinal axis

  dinal 24 of the nozzle. However, it has several separate depressions,

  equidistant and arranged in several perpendicular rows.

  The substantially identical recesses 25 are of cubic form in the exemplary embodiment shown. Other forms are however conceivable. It is also conceivable to replace the 25

  separated by separate bosses on the bottom of the turbulence chamber.

  lence. A realization of said bottom with hollows and bosses

  separate seems also possible. or.

  The distance A between the piercing hole 12 of the liquid inlet, opens

  edge in the turbulence chamber 14, and the bottom 23 of the latter is equal to about one tenth of the diameter d of the end

  of drilling 12, as shown in Figure 1. As a result of this relationship,

  between the liquid inlet bore 12 and the bottom 23 of the

  turbulence chamber, the separated hollows exert an optimum

  male on the desired production of a solid cone.

  The second front face 22 mentioned above of the discoidal piece 18

  on the other hand is perfectly flat, that is to say does not involve any

  wise or hollow. The use of this front face 22 as the background of the

  turbulence chamber makes it possible to obtain a hollow jet cone.

  Screws for example, represented by the straight lines 26 in dots and dashes, allow the removable fixing of the discoid piece 18,

  which can be replaced or returned as described.

  The cylindrical piece 18a constitutes the bottom 23a of the chamber of

  turbulence in the embodiment according to FIGS. 3 and 4. The example

  represented pie comprises in total three bosses 27, made by milling with end mills. The required positions of the cutters are indicated by the dotted and dashed lines 28. Figure 3

  shows that the three millings 28 are located on the same primary circle

  tif 29, according to the circumference of which they have a regular angular interval of 1200. The diameter of this circle 29 is lower

  the outer diameter of the bottom 23a of the turbulence chamber. The exam-

  Embodiment according to Figures 3 and 4 further comprises an additional milling (circle dots and dashes 30), made in the center of the bottom 23a of the turbulence chamber and which removes the material

  still connecting the various bosses 27.

  It should be emphasized, however, that the invention is not limited to the representation according to FIGS. 3 and 4. Thus, in practice, the circumference often has more than the three millings (shown in FIG. to produce a greater number of bosses and hollows. The millings must not necessarily be on the same pitch circle 29, nor be equidistant according to the circumference. The diameter of the primitive circle

  29, where there is one, need not be inferior

248539î

  than the bottom 23a of the turbulence chamber; he can too

  to be equal or superior. In many cases, it is not rigorous

  It is essential to perform concentric milling in addition to peripheral milling. It is conceivable to keep the material bridges in the center of the bottom of the turbulence chamber, so

to produce separate troughs 28.

  The machining of the bottom 23a of the turbulence chamber by milling

  wise of the same diameter, the same angular spacing and on a circle

  however, there are important technical advantages

  manufacturing processes compared to machining irregular geometry

  especially when machining on a milling machine

circular (clocked machining).

  Of course, various modifications can be made by those skilled in the art to the principle and to the devices which have just been described as non-limiting examples, without departing from the

framework of the invention.

Claims (18)

claims   1. Full cone spray nozzle with one chamber   of cylindrical turbulence, a liquid inlet opening tangen-   in the latter and an outlet nozzle axially extending the turbulence chamber and flow direction perpendicular to the arrival of the liquid, and depressions and bosses machined on the bottom of the turbulence chamber facing the nozzle of outlet, in order to influence the flow of the liquid, said nozzle being characterized in that the bottom (23) of the turbulence chamber   has several depressions (25) and / or separate bosses.   2. Full cone spray nozzle according to claim 1,   characterized in that the depressions and / or bosses have a provision regular geometric layout.   3. Spray nozzle in solid cone according to one of the claims   1 and 2, characterized in that the depressions and / or separate bosses   are equidistant and arranged in several perpendicular rows lar.   4. Spray nozzle in solid cone according to one of the claims   1 and 2, characterized in that the depressions and / or separate bosses   are made by machining the bottom of the turbulence chamber,   pendicular to its surface, using end mills.   5. A solid cone spray nozzle according to claim 4, characterized in that the milling (28) is performed on a pitch circle (29), the diameter of which is smaller than the outside diameter.   from the bottom (23a) of the turbulence chamber.   6. Spray nozzle in solid cone according to one of the claims   4 or 5, characterized in that the millings (28) are equidistant   following the circumference of the bottom (23a) of the turbulence chamber   lence. 7. Full cone spray nozzle according to any one of   Claims 4 to 6, characterized by additional milling   (30) in the center of the bottom (23a) of the turbulence chamber.   8. Solid cone spray nozzle according to any one of   Claims 1 to 3, characterized in that the recesses (25) and / or   bosses are polyhedral, and preferably cubic, pyramidal, or truncated pyramid.   9. Full cone spray nozzle according to any one of   Claims 1 to 3, characterized in that the recesses and / or bosses are conical or frustoconical.   10. Full cone spray nozzle according to any one of   Claims 1 to 9, characterized by equal dimensions of all   the hollows (25) and bosses, or at least the vast majority of them.   Spray nozzle according to any one of the claims   - o 1 to 10, characterized by a removable connection of the bottom (23) of the turbulence chamber and the body (10) of the nozzle forming said bedroom (14).   A solid cone spraying nozzle according to claim 11, characterized by a flange piece (18) forming the bottom (23) of the turbulence chamber and removably secured by a flange (19).   on the rear face of the body (10) of the nozzle.   13. A solid cone spray nozzle according to claim 12, characterized in that the piece of discord 18) can be fixed on the body (10) of the nozzle, in two positions offset by 1800 with respect to its transverse axis, so that both sides   front (23, 22) of said room may constitute the bottom of the room. turbulence.   14. Spray nozzle in solid cone according to one of the claims   12 and 13, characterized in that the fixing flange (19) forming the outer edge of the disconnected piece (18) is staggered on both sides, with respect to the two end faces (22, 23) of said   - piece (18), so that on each side of the flange extends an over-   cylindrical face (20, 21), whose outside diameter is equal to the inside diameter of the turbulence chamber (14) and which centers   the piece discord (18) relative to the body (10) of the nozzle.   15. Solid cone nozzle according to any of the claims   12 to 14, characterized in that one (22) of the two end faces (22, 23) of the discord piece (18) is flat, that is to say does not comprise no hollow or boss.   16. Full cone spray nozzle according to any one of   Claims 1 to 15, characterized in that the distance (A) between   the hole or holes (12) for the arrival of the liquid, opening tangentially   in the turbulence chamber, and the point of the   coid (18) forming the bottom (23) of said chamber, the closest to the inlet bore (12), is equal to about one tenth of the diameter (d) of the inlet orifices of the liquid, measured according to the axis of the turbulence chamber.   17. Full cone spray nozzle according to any one of   Claims 1 to 16, characterized in that the bottom (23) of   the turbulence chamber, including the bosses and / or recesses (25), or the discord piece (18) forming the said bottom is a plastic part injection molded.   18. Full cone spray nozzle according to any one of   Claims 1 to 16, characterized in that the bottom (23) of the   turbulence chamber, including the bosses and / or recesses (25), or the discord piece (18) forming said bottom is a metal piece,   milled by uninterrupted milling, using coupled cutters.